Method and system for initiating idle handoff in a wireless communications system

1. A method of initiating idle handoff of a mobile station in a wireless communications system, comprising the steps of: (A) obtaining first and second samples of a first pilot signal radiated by a first base station, said first sample occurring at a first time and said second sample occurring at a second time; (B) obtaining third and fourth samples of a second pilot signal radiated by a second base station, said third sample occurring at said first time and said fourth sample occurring at said second time; (C) determining whether the sum of the difference between the total strengths of said second and fourth samples and a position-weighting term is less than a first design parameter; and (D) initiating idle handoff of said mobile station from said first base station to said second base station if said sum is less than said first design parameter.

2. The method of claim 1 wherein the value of said position-weighting term (PW) is determined in accordance with the following equation: EQU PW=[M.times.(POS.sub.A (t2)-POS.sub.A (t1))]-[N.times.(POS.sub.B (t2)-POS.sub.B (t1))] where M is a second design parameter, N is a third design parameter, POS.sub.A (t2) comprises a value related to the distance of said mobile station from said first base station at said second time, POS.sub.A (t1) comprises a value related to the distance of said mobile station from said first base station at said first time, POS.sub.B (t2) comprises a value related to the distance of said mobile station from said second base station at said second time, and POS.sub.B (t1) comprises a value related to the distance of said mobile station from said first base station at said first time.

3. The method of claim 1 wherein the value of said position-weighting term (PW) is determined in accordance with the following equation: PW=[M.times.(POS.sub.A (t2)-POS.sub.A (t1)).times.(Ee.sub.A (t2)/E.sub.A (t2))]-[N.times.(POS.sub.B (t2)-POS.sub.B (t1)).times.(Ee.sub.B (t2)/E.sub.B (t2))] where M is a second design parameter, N is a third design parameter, POS.sub.A (t2) comprises a value related to the distance of said mobile station from said first base station at said second time, POS.sub.A (t1) comprises a value related to the distance of said mobile station from said first base station at said first time, POS.sub.B (t2) comprises a value related to the distance of said mobile station from said second base station at said second time, POS.sub.B (t1) comprises a value relate to the distance of said mobile station from said first base station at said first time, E.sub.A (t2) comprises said total strength of said second sample, E.sub.B (t2) comprises said total strength of said fourth sample, Ee.sub.A (t2) comprises the strength of the earliest arriving usable multipath component of said second sample, and Ee.sub.B (t2) comprises the strength of the earliest arriving usable multipath component of said fourth sample.

4. The method of claim 2 or 3, wherein POS.sub.A (t2) comprises the phase offset of the earliest arriving usable multipath component of said second sample, POS.sub.A (t1) comprises the phase offset of the earliest arriving usable multipath component of said first sample, POS.sub.B (t2) comprises the phase offset of the earliest arriving usable multipath component of said fourth sample, and POS.sub.B (t1) comprises the phase offset of the earliest arriving multipath component of said third sample.

5. The method of claim 1 wherein said wireless communications system is a cellular communications system.

6. The method of claim 1 wherein said wireless communications system is a CDMA system.

7. The method of claim 6 wherein said mobile station is in the idle state and said first and second pilot signals comprise first and second pilot channels.

8. The method of claim 7 wherein said total strengths of said samples are calculated by adding the ratios of energy per chip of said pilot. channels to total spectral density of at most k usable multipath components of said pilots received during said samples.

9. The method of claim 1 wherein said mobile station periodically performs said sampling steps.

10. The method of claims 1, 2 or 3 wherein said first design parameter has a value in the range of approximately 2.0-approximately 3.0.

11. The method of claims 2 or 3 wherein said second design parameter has a value in the range of approximately 0.8-approximately 1.1, and said third design parameter has a value in the range of approximately 1.0-approximately 1.5.

12. A system for determining whether to initiate idle handoff in a wireless communications system, comprising: (A) a first base station radiating a first pilot signal; (B) a second base station radiating a second pilot signal; and (C) a mobile station having an integrated chip capable of executing software; and (D) a set of software instructions executed by said chip for: (i) obtaining first and second samples of said first pilot signal, said first sample occurring at a first time and said second sample occurring at a second time; (ii) obtaining third and fourth samples of said second pilot signal, said third sample occurring at said first time and said fourth sample occurring at said second time; (iii) determining whether the sum of the difference between the total strengths of said second and fourth samples and a position-weighting term is less than a first design parameter; and (iv) initiating idle handoff of said mobile station from said first base station to said second base station if said sum is less than said first design parameter.

13. The system of claim 12 wherein the value of said position-weighting term (PW) is determined in accordance with the following equation: EQU PW=[M.times.(POS.sub.A (t2)-POS.sub.A (t1))]-[N.times.(POS.sub.B (t2)-POS.sub.B (t1))] where M is a second design parameter, N is a third design parameter, POS.sub.A (t2) comprises a value related to the distance of said mobile station from said first base station at said second time, POS.sub.A (t1) comprises a value related to the distance of said mobile station from said first base station at said first time, POS.sub.B (t2) comprises a value related to the distance of said mobile station from said second base station at said second time, and POS.sub.B (t1) comprises a value related to the distance of said mobile station from said first base station at said first time.

14. The system of claim 12 wherein the value of said position-weighting term (PW) is determined in accordance with the following equation: EQU PW=[M.times.(POS.sub.A (t2)-POS.sub.A (t1)).times.(Ee.sub.A (t2)/E.sub.A (t2))]-[N.times.(POS.sub.B (t2)-POS.sub.B (t1)).times.(Ee.sub.B (t2)/E.sub.B (t2))] where M is a second design parameter, N is a third design parameter, POS.sub.A (t2) comprises a value related to the distance of said mobile station from said first base station at said second time, POS.sub.A (t1) comprises a value related to the distance of said mobile station from said first base station at said first time, POS.sub.B (t2) comprises a value related to the distance of said mobile station from said second base station at said second time, POS.sub.B (t1) comprises a value relate to the distance of said mobile station from said first base station at said first time, E.sub.A (t2) comprises said total strength of said second sample, E.sub.B (t2) comprises said total strength of said fourth sample, Ee.sub.A (t2) comprises the strength of the earliest arriving usable multipath component of said second sample, and Ee.sub.B (t2) comprises the strength of the earliest arriving usable multipath component of said fourth sample.

15. The system of claim 13 or 14, wherein POS.sub.A (t2) comprises the phase offset of the earliest arriving usable multipath component of said second sample, POS.sub.A (t1) comprises the phase offset of the earliest arriving usable multipath component of said first sample, POS.sub.B (t2) comprises the phase offset of the earliest arriving usable multipath component of said fourth sample , and POS.sub.B (t1) comprises the phase offset of the earliest arriving multipath component of said third sample.

16. The system of claim 12 wherein said wireless communications system is a cellular communications system.

17. The system of claim 12 wherein said wireless communications system is a CDMA system.

18. The system of claim 17 wherein said mobile station is in the idle state and said first and second pilot signals comprise first and second pilot channels.

19. The system of claim 18 wherein said total strengths of said samples are calculated by adding the ratios of energy per chip of said pilot channels to total spectral density of at most k usable multipath components of said pilots received during said samples.

20. The system of claim 12 wherein said mobile station periodically performs said sampling steps.

21. The system of claim 12, 13 or 14 wherein said first design parameter has a value in the range of approximately 2.0-approximately 3.0.

22. The system of claim 13 or 14 wherein said second design parameter has a value in the range of approximately 0.8-approximately 1.1, and said third design parameter has a value in the range of approximately 1.0-approximately 1.5.

23. A system for initiating idle handoff of a mobile station in a wireless communications system, comprising: (A) means for obtaining first and second samples of a first pilot signal radiated by a first base station, said first sample occurring at a first time and said second sample occurring at a second time; (B) means for obtaining third and fourth samples of a second pilot signal radiated by a second base station, said third sample occurring at said first time and said fourth sample occurring at said second time; (C) means for determining whether the sum of the difference between the total strengths of said second and fourth samples and a position-weighting term is less than a first design parameter; and (D) means for initiating idle handoff of said mobile station from said first base station to said second base station if said sum is less than said first design parameter.

24. The system of claim 23 wherein the value of said position-weighting term (PW) is determined in accordance with the following equation: EQU PW=[M.times.(POS.sub.A (t2)-POS.sub.A (t1))]-[N.times.POS.sub.B (t2)-POS.sub.B (t1))] where M is a second design parameter, N is a third design parameter, POS.sub.A (t2) comprises a value related to the distance of said mobile station from said first base station at said second time, POS.sub.A (t1) comprises a value related to the distance of said mobile station from said first base station at said first time, POS.sub.B (t2) comprises a value related to the distance of said mobile station from said second base station at said second time, and POS.sub.B (t1) comprises a value related to the distance of said mobile station from said first base station at said first time.

25. The system of claim 23 wherein the value of said position-weighting term (PW) is determined in accordance with the following equation: EQU PW=[M.times.(POS.sub.A (t2)-POS.sub.A (t1)).times.(Ee.sub.A (t2)/E.sub.A (t2))]-[N.times.(POS.sub.B (t2)-POS.sub.B (t1)).times.(Ee.sub.B (t2)/E.sub.B (t2))] where M is a second design parameter, N is a third design parameter, POS.sub.A (t2) comprises a value related to the distance of said mobile station from said first base station at said second time, POS.sub.A (t1) comprises a value related to the distance of said mobile station from said first base station at said first time, POS.sub.B (t2) comprises a value related to the distance of said mobile station from said second base station at said second time, POS.sub.B (t1) comprises a value relate to the distance of said mobile station from said first base station at said first time, E.sub.A (t2) comprises said total strength of said second sample, E.sub.B (t2) comprises said total strength of said fourth sample, Ee.sub.A (t2) comprises the strength of the earliest arriving usable multipath component of said second sample, and Ee.sub.B (t2) comprises the strength of the earliest arriving usable multipath component of said fourth sample.